Workholding &
Rotary Tables
Last updated on
Thursday, October 21, 2010 06:30:44 PM
Eastern US Time Zone
Mill Vise, Indicating a
Mill Vise, Drawbar Tool,
Work Stops, Edge Finders,
Safety Shields
Parallel
Sets, Precision Blocks,
Work Hold-down Clamps, Rotary Tables,
Dividing Head
Mill Vise
Parlec PSW-6900
6" wide angle-lock vise (Taiwan). 75 lbs., 9" opening. 1.75" jaw depth. Bed height 2.875" ±0.0005".
Parallelism of base to bed 0.0006".
Perpendicularity of jaws to bed 0.0005".
Flatness of base 0.001".
Repeatability within 0.001". Hardened vise bed & jaw plates. Outside rail edges
of the body machined.
80,000 PSI high nickel ductile iron.
8200 lbs clamping pressure. Powder paint & sealed bearing system.
Larger, precision main screw & bolted solid jaw allow higher torque loads.
Dimensions are industry standard.
Another reason why I chose the Parlec vise was because the equivalent, Kurt
Model D675, when fully
closed,
has a movable-jaw nut that protrudes out the back (1.4") which would interfere with table travel
on a smaller mill.
The Parlec does not have a protruding nut. Both
Kurt
& Parlec
sites have mechanical drawings for reference.
Parlec PWS-6900 Single Station vise
parts list.
Indicating a Mill Vise
A common question
is, "When I machine a surface using an end mill, why do I get a small ridge after
each pass?"
The answer may be that the mill needs to be indicated (aligned). The spindle
(cutter) must be perpendicular re the table.
Other causes may include: excessive machine flex, improperly held cutter (e.g.,
a drill chuck), and/or a dull/damaged end mill.
Indicating the Parlec solid jaw, animation. The slot on the
top of the solid jaw can also be used.
See instructions on how to
set tip geometry
& see illustration.
Indicating the Parlec vise's bottom surface, animation.
A two-position speed handle that was free with the vise purchase.
Kurt spring-loaded parallels separator.
Especially holds the ultra-thin parallels nicely in
place.
Prismatic V-jaw.
Drawbar Tool
Fabricated a 17mm drawbar wrench with an integral brass hammer. Loosen the mill's
hardened nut & give it a tap.
Used a ⅜" carbide end mill to make a hole through the
Craftsman six-sided (for strength) deep socket for the
tightly-fitting steel handle.
There are milled flats on both sides of the hole. The locknut fits inside the
milled flat edges. The handle is located midpoint.
The brass head has a tight-fitting peg pressed into the square hole & is held in using an
⅛" roll-pin.
There is a heavy, 45° chamfer on the hammer's face edge. The longer handle
allows a tighter draw down &
the socket
keeps the nut in good condition. The open-ended wrench was shorter & caused
micro-burrs
which I had to stone off so the socket would slide on & off smoothly.
Work Stops
This stop attaches to either the back or front side of the jaws' threaded holes.
It is below the top of the jaws.
This work stop, which is below the part, attaches to the mill table & is shown fixing the position of a
5C fixture.
The stop is clamped only on the solid vise jaw.
Edge Finders
Electronic edge finder with a ¾" shank. The 0.400" diameter ball tip is spring-loaded to
prevent
damage
from over travel.
When the edge is detected, zero the DRO, retract the
quill then move
the axis
½ the distance of the ball's radius (0.200") & then zero
the DRO, again.
Electronic edge finder manual.
LED edge finder animation. Note how the self-centering, spring-loaded ball
allows over travel without damage.
See more vises.
A variety of edge detectors & center finders with ¾".
½", & ⅜" shanks. The spindle is turning.
The wiggler-type (right) works best at about 1000 RPM. The LS Starrett brand is superior.
Using a center finder to zero the DROs. The spindle turns & the point is
centered by gently pressing on it.
Edge finder animation. The spindle is turning at about 1000 RPM.
⅜" diameter
Starrett edge finder with its adapter so
you don't have to change a collet just to indicate an edge.
Step sizes: ¼", 5/16", ⅜", ½",
⅝", ¾" and
1". Step depths vary from .100" to .200".
A stepped center indicator for quick alignments. Made out of stainless steel rod.
¼", 5/16", ⅜", ½" steps.
For the most accurate indication, use a
center finder or
dial test indicator.
Safety Shields
Small, low, 1/16" thick, polycarbonate chip shield.
The aluminum
base has five glued-in magnets.
Three, 6-32 set screws hold the shield into the base.
Larger polycarbonate shield on a magnetic base.
SS holder rod with aluminum edge holder.
Works on the lathe, too.
Parallel
Sets
Parallels accurately hold a work piece
or fixture at different depths in the
mill vise jaws.
6" long, 1/32" (0.032") ultra-thin, ½" through 1-11/16" by 1/16"
increments.
Needed when working close the the piece's edge and/or gripping near the top (1/16")
of the vise jaws.
Parallelism ±0.0001". These ultra-thins also clear the tightening
nut of the 5C collet fixture
when it is used
in a vertical position. To keep closely-spaced parallels separated, I place a
piece of foam in-between them.
A drop of light instrument oil will also stick parallels to the vise
jaws. For wider openings, I use a Kurt separator.
6" long, ⅛" thick, ½"
through 1⅝" by ⅛" increments, standard parallel set.
6" long, ¼" thick, ¾"
through 1¾" by ⅛" increments parallel set.
6" long, ½" thick, ⅞" through
1¾" by ⅛" increments parallel set. Accuracy ±0.0003".
These thicker parallels form a very stable part base when there is enough room
for them.
Adjustable parallels. Two sets are handy. Can also be used to gage inside
dimensions.
There are also 4½"
long,
wavy parallels made out of
spring material that compress for holding small pieces.
3-inch long, parallel set.
Precision Blocks
Accurate,
1-2-3, 2-3-4 & 2-4-6 (inches) precision-ground, hardened, steel blocks.
⅜-16 threaded & clearance holes allow clamping.
The 2-4-6 blocks are shown being used to stiffen the setup.
Animation illustrating the use of precision blocks to help
indicate the RF-25 table.
RF-25 mill table slot dimensions where: 24mm = 0.945", 14mm = 0.551",
& 10mm = 0.394".
Work Hold-down Clamps
The RF-25 slots require ½" T-Nuts using
⅜" studs.
Hold-down clamp set.
Rotary Tables
Six-inch Phase
II+ rotary table. Perfect size for the RF-25 table (40
lbs).
Worm gear can cam out of mesh to
allow free/rapid rotation of the table.
Before use,
remove the table scale index retention knob that is above the
front left table locking lever, in order to fill
the oil reservoir through the hole.
Plastic reservoir window to the right
of the front locking lever shows the oil level. Filled it to the middle of the window with Starrett light instrument oil.
Phase2+ Rotary Table manual.
Tramming the rotary table using an IndicOL holder with
Starrett dial
test indicator (above) &
a ⅛" collet holding a dial test indicator (below).
Animation showing the left-right (X-axis) of the rotary table being trammed using the
precision ground inner edge.
Animation showing the front-back (Y-axis) of the rotary table being trammed.
The 4"
Sherline rotary table has a ⅜-16 threaded center
which is very handy when attaching parts.
The 6" table has an MT2 taper (1.5º) in the center so I made a tapered plug with
⅜-16 threads.
There is still room to tram using the inner edge.
A bottom view of the 6" rotary table showing a bolt holding the plug firmly in the
MT2 hole.
Detail of the brass plug.
6" rotary table with 6" 4-jaw chuck
mounted.
Drilled (Q) & counter-bored (½" end mill) four holes for 5/16-18
hardened hex
bolts.
The bolts are halfway (45°) between the jaws & the threaded holes that mount the
back
plate.
First tram the rotary table then tram the chuck using the outside surface.
Using the rotary table to layout the bolt-hole pattern for the 4" chuck to 6"
rotary adapter plate.
Precision
(reamed) center hole used to indicate part center in the 4-jaw chuck.
Engaged all table locks before drilling.
M8-1.25 counter sunk hex bolts use the existing
chuck adapter plate holes.
Hardened 5/16-18 hex
bolts hold the plate to the 6" rotary table.
The aluminum plate is made from high-precision (milled) stock.
Bolted a narrow, milled bar with ⅜-16 threaded
mounting holes onto the bottom of the rotary table.
Just clamp it into the vise with the bottom of the table resting on
the top of the precision machined jaws.
The table aligns fine & it is quicker than removing & re-installing the
75
lbs.
Parlec vise.
4⅝" of Z are lost but if the part is small, no problem. The rotary table is also
better centered.
Also mounted the 4" rotary table onto a base plate
for quick mounting.
The table already had three, 10-32
threaded holes on the bottom.
Use transfer screws
to align the three, 10-32 threaded holes with the plate.
The rotary table's bottom surface rests on the vise jaws.
For an additional 1¾" of Z, the plate will allow holding down inside the jaws.
Parallels can be used, too. The
base plate has (10) holes that align with the Taig mill table T-slots to allow direct
mounting using 10-32 bolts.
An aluminum collar was machined to attach & center the part using a ⅜-16
bolt screwed into the table's center.
Made an adapter plate to mount the 4" rotary table centered
on the tilt table.
Dividing Head
Dividing head with its center & integral dog. The 1½-8
threads are protected by the supplied plastic collar.
Also shown is its adjustable tailstock. Threaded (unfinished) chuck adapter
& additional index plates (top).
Dividing head with 5C collet chuck. The
head can tilt to different angles. Bemato dividing head manual.
This dividing head is made by Bemato
(Taiwan).
This head is now used on the RF-25 mill.
Use a 4-jaw
or collet chuck to get better centering.
A three-jawed chuck may not hold the stock perfectly centered.
See Gears guide.
First try results.
Next time I would use the large mill with the collet chuck or 4-jaw
chuck to get the stock centered.
An involute gear cutter is best however they are quite expensive.
I have switched to CNC
as a
better alternative to making gears & involute cutters are also being
considered.
Involute gear animation.
Mill Vise, Indicating a
Mill Vise, Drawbar Tool,
Work Stops, Edge Finders,
Safety Shields
Parallel
Sets, Precision Blocks,
Work Hold-down Clamps, Rotary Tables,
Dividing Head